Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: UNIPROT:P50583 (
asymmetrical
)
12,197
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
1. The generation of egg-laying behavior in the marine mollusk Aplysia involves a prolonged burst discharge in the neuroendocrine bag cells, which secrete neuropeptides derived from the egg-laying hormone/bag cell peptide (ELH/
BCP
) precursor protein. 2. Besides the bag cells, which are located in the abdominal ganglion, small clusters of neurons in the cerebral and pleural ganglia also express the ELH/
BCP
neuropeptides. We made intracellular recordings from 32 of these ELH/
BCP
cells in right pleural ganglia, in 18 preparations, to characterize their physiological properties and their functional relationship to the bag cells. 3. The identification of these ELH/
BCP
cells was confirmed by pressure injection of Lucifer yellow and subsequent immunocytochemical processing for alpha-
BCP
immunoreactivity. 4. The basic electrophysiological properties of the pleural ELH/
BCP
cells were similar to those of the bag cells. These pleural cells were directly demonstrated to be electrically coupled, and direct intracellular stimulation of individual pleural ELH/
BCP
cells initiated prolonged, synchronous burst discharges in the entire cluster through a positive feedback mechanism. 5. Burst discharges elicited in the pleural ELH/
BCP
cells consistently initiated burst discharges in the bag cells. Bag cell burst discharges were less effective in initiating burst discharges in the pleural ELH/
BCP
cells, indicating that there were reciprocal but
asymmetrical
connections. 6. The results show that the pleural ELH/
BCP
cells are functionally coupled to the bag cells. They support the hypothesis that the pleural ELH/
BCP
cells are part of the descending pathway that initiates bag cell activity and egg-laying behavior, in vivo.
...
PMID:Neuroendocrine bag cells of Aplysia are activated by bag cell peptide-containing neurons in the pleural ganglion. 274 15
Recent experiments show that external inplanar electric field can be employed to guide the molecular self-assembly in diblock copolymer (
BCP
) thin films to form lamellar nanostructures with potential applications in nanotechnology. We study this self-assembly process through a detailed coarse-grained phase-separation modeling. During the process, the free energy of the
BCP
films is modeled as the Ginzburg-Landau free energy with nonlocal interaction and electrostatic coupling. The resulting Cahn-Hilliard (CH) equation is solved using an efficient semi-implicit Fourier-spectral algorithm. Numerical results show that the morphology of order parameter formed in either symmetric or asymmetric
BCP
thin films is strongly influenced by the electric field. For symmetrical BCPs, highly ordered lamellar nanostructures evolved along the direction of the electric field. Phase nucleation and dislocation climbing in the
BCP
films predicted by the numerical simulation are in a good agreement with those observed in recent
BCP
electronanolithography. For
asymmetrical
BCPs, numerical simulation shows that nanodots are guided to align to the electric field. Furthermore, in the case of high electric field, nanodots formed in
asymmetrical
BCPs may further convert into highly ordered lamellar nanostructures (sphere-to-cylinder transition) parallel to the electric field. Effects of the magnitude of electric field,
BCP
asymmetry, and molecular interaction of BCPs on the self-assembly process are examined in detail using the numerical scheme developed in this study. The present study can be used for the prediction of the formation of nanostructures in
BCP
thin films and the quality control of
BCP
-based nanomanufacturing through optimizing the external electric fields.
...
PMID:Phase-field modeling of the formation of lamellar nanostructures in diblock copolymer thin films under inplanar electric fields. 1851 14
